Intravenous fluid warming system

ABSTRACT

A fluid warming device may include a housing comprising a main body, a heat exchange body receiving compartment, and a cover movably coupled to the main body between an open position and a closed position; a heater assembly disposed within the main body and having a heat conducting surface disposed proximate the heat exchange body receiving compartment; and a heat exchange body removably disposable in the heat exchange body receiving compartment of the main body and having an input port and an output port to couple the heat exchange body to tubing to flow a fluid to be warmed through the heat exchange body. In another aspect, a fluid warming system increases or decreases power to a heater assembly to adjust the fluid temperature to ensure that the fluid is at an appropriate temperature when it reaches the patient.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of co-pending U.S. patent application Ser. No. 12/983,420, filed Jan. 3, 2011 and issued on Apr. 3, 2012 as U.S. Pat. No. 8,150,244, which is a divisional of U.S. patent application Ser. No. 11/385,085, filed Mar. 21, 2006 and issued as U.S. Pat. No. 7,865,072, which claims benefit of United States provisional patent application Ser. No. 60/663,857, filed Mar. 21, 2005. Each of the aforementioned related patent applications is herein incorporated by reference.

BACKGROUND

Intravenous (IV) fluid warming devices are known that heat an IV fluid prior to introducing the fluid into a patient. Warmed IV fluids that are administered at very low flow rates can cool as they flow down the IV tubing to the patient. Often this heat loss is ignored. One prior art approach has been to simply heat the fluid to 41° C. to try to overcome the loss for all flow rates.

In another aspect of fluid warming, most IV fluid warmers heat fluid through flexible plastic walls. Because these walls are inefficient in transferring heat, heaters are exposed to both sides of the disposable set. This requires inserting the disposable set into a slot or hinged clam shell configuration. Both of these designs do not allow the user to see the fluid passing through the heat exchanger. As these plastic walls are flexible, the pressure necessary for good heat transfer cannot be guaranteed as it is supplied only by the gravitational force of the IV fluid bag height. Cleaning of configurations with slots is difficult and typically requires special tools or even disassembly, such as in the case of blood spills.

One type of exemplary medical fluid warming system is described in U.S. 2005-0008354. In this device, fluid passes along a generally serpentine fluid flow path through a removable/disposable heat exchange body. The heat exchange body is in thermal contact with a resistive film heater via thermally conductive layers interposed between the heat exchange body and the heater. Temperature sensors are provided that sense the temperature of the heat exchange body and of the heater.

SUMMARY OF THE INVENTION

In some embodiments, a fluid warming device may include a housing comprising a main body, a heat exchange body receiving compartment, and a cover movably coupled to the main body between an open position and a closed position; a heater assembly disposed within the main body and having a heat conducting surface disposed proximate the heat exchange body receiving compartment; and a heat exchange body removably disposable in the heat exchange body receiving compartment of the main body and having an input port and an output port to couple the heat exchange body to tubing to flow a fluid to be warmed through the heat exchange body.

In some embodiments, a method of minimizing heat loss through IV tubing to a patient may include a) determining a temperature drop across a heat exchange body of an IV fluid warming device; b) determining a temperature drop of the IV tubing to the environment, the IV tubing extending from the IV fluid warming device to the patient; c) determining if the temperature drop along the IV tubing is greater than a determined temperature limit; d) determining if the total temperature drop along the IV tubing and across the heat exchange body is greater than a determined drop limit; e) if the determined values from c) or d) are greater than their respective limits, determining the actual fluid temperature as a fluid output temperature minus the drop limit; f) if either of the determined values from c) or d) are not greater than their respective limits, determining the actual fluid temperature as a fluid output temperature minus the heat exchanger temperature drop; and g) adjusting power to the heat exchanger to achieve a desired output temperature.

In some embodiments a method of minimizing heat loss through IV tubing to a patient may include a) providing a heat exchange body, coupled between an IV fluid source and the patient via IV tubing, to a heat exchange body receiving compartment of an IV fluid warming device that comprises a housing including a main body, the heat exchange body receiving compartment, a cover movably coupled to the main body between an open position and a closed position, and a heater assembly disposed within the main body and having a heat conducting surface disposed proximate the heat exchange body receiving compartment such that the heat exchange body is in heat exchange communication with the heater assembly; b) determining a temperature drop across the heat exchange body by dividing heater power of the heater assembly by the thermal resistance of the heater assembly; c) determining a temperature drop of the IV tubing to the environment, the IV tubing extending from the IV fluid warming device to the patient, by determining the difference between a fluid target temperature and ambient temperature, multiplying this difference by a radiation loss constant to get a result, and dividing the result by heater power of the heater assembly; d) determining if the temperature drop along the IV tubing is greater than a determined temperature limit; e) determining if the total temperature drop along the IV tubing and across the heat exchange body is greater than a determined drop limit; f) if the determined values from d) or e) are greater than their respective limits, determining the actual fluid temperature as a fluid output temperature minus the drop limit; g) if either of the determined values from d) or e) are not greater than their respective limits, determining the actual fluid temperature as a fluid output temperature minus the heat exchanger temperature drop; and h) adjusting power to the heat exchanger to achieve a desired output temperature.

DESCRIPTION OF THE DRAWINGS

The invention will be more fully understood from the following detailed description taken in conjunction with the accompanying drawings in which:

FIG. 1 is an isometric view of a fluid warming device illustrating slidable covers in a closed position according to the present invention;

FIG. 2 is an isometric view of the fluid warming device of FIG. 1 illustrating the slidable covers in a half closed position;

FIG. 3 is an isometric exploded view of the fluid warming device of FIG. 1 with the slidable covers in an open position and a disposable set removed;

FIG. 4 is an isometric view of a main body of the housing of the device of FIG. 1 with the slidable covers fully removed;

FIG. 5 is a plan view of the device of FIG. 2;

FIG. 6 is a cross sectional view taken along line A-A of FIG. 5;

FIG. 7 is a schematic view of a disposable set and heater assembly of the fluid warming device of FIG. 1;

FIG. 8 is a side view of a further embodiment of a fluid warming device illustrating gripping faces on the slidable covers;

FIG. 9 is a flow chart illustrating a system for adjusting power to a heater of a fluid warming device to accommodate heat loss in an IV tubing at low flow rates;

FIG. 10 is a graph illustrating heat loss across a disposable set heat exchange body and along a length of IV tubing and their combined heat losses; and

FIG. 11 is a graph illustrating temperature loss for various lengths of IV tubing and various flow rates.

DETAILED DESCRIPTION

A fluid warming device 10 according to the present invention is illustrated in FIGS. 1-7. The fluid warming device includes a housing 12 having a main body 14 and two sliding covers 16. Within the housing, supported by the main body, are a removable heat exchange body 18 and a heater assembly 20. The sliding covers are independently slidable to a closed position in which they retain the removable heat exchange body in place, as described more fully below. The slidable covers are preferably identical.

The removable heat exchange body 18 and the heating assembly 20 are illustrated schematically in FIG. 7. The heat exchange body, also called a disposable or removable set, includes an input port 22 connectable to an IV tubing line from a source of IV fluid, which may include an infusion pump. The disposable set also includes an output port 24 connectable to a further IV tubing line to deliver the IV fluid to the patient. Within the disposable set, the IV fluid flows along a flow path (not shown) having a serpentine or other suitable configuration between the input and output ports to optimize heat transfer to the fluid. See, for example, US Patent Pub. No. 2005-0008354, the disclosure of which is incorporated by reference herein. The disposable set is formed from any suitable material, such as aluminum, to facilitate heat transfer to the fluid flowing therein. When inserted in the housing with the sliding covers in a closed position, the disposable set is held in thermal contact with the heater assembly, so that heat transfer from the heater assembly to the disposable set causes heating of an IV fluid flowing therethrough.

The heater assembly 20 is affixed within the main body 14 of the housing 12. The heater assembly includes a heater 26 and one or more thermally conductive layers 28, 30 interposed between the disposable set and the heater. Preferably, the heater is an electrically powered resistive thin film heater. A power line 32 to the heater from a suitable power source is provided. Alternatively, the device may include a battery compartment or a connection to a battery pack, for example, for portable operation. Temperature sensors 34, 36 are provided that sense the temperature of the disposable set and of the heater. See, for example, US Patent Pub. No. 2005-0008354. The thermally conductive layers also electrically insulate the disposable set from the resistive heater. One thermally conductive layer 28 may suitably comprise a phase transition material, and the other thermally conductive layer 30 may suitably comprise a material such as a graphite to optimize heat transfer between the heater and the disposable set. See, for example, US Patent Pub. No. 2005-0008354. It will be appreciated that other or further thermally conductive layers may be provided. The main body 14 includes a compartment 38 on one side to receive the disposable set 18 in contact with an exposed surface 40 of the uppermost thermally conductive layer 30.

As noted above, the heat exchange body or disposable set 18 is removable from the housing. The disposable set can be removed from the main body of the housing by sliding the two opposed sliding covers outwardly in opposite directions. In this manner, the removable set can be lifted out of the housing with the IV tubing still attached to the input and output connectors, without breaking the fluid path. Finger cutouts 42 may be provided for ease of grasping the disposable set in the main body.

Any suitable sliding mechanism to allow the covers to move axially into the closed position can be provided. In the embodiment shown, the main body 14 of the housing includes protruding longitudinal tracks 46 along two opposed longitudinal outer wall surfaces of the main body. See FIG. 5. The sliding covers include complementary longitudinal recesses 48 along inner wall surfaces that mate with the tracks and allow the covers to slide axially along the main body. When in the closed position, the sliding covers extend over the edges of the disposable set within the recess of the main body, thereby retaining the disposable set therein. See FIG. 1. The covers also compress the disposable set to the outermost thermally conducting surface 40 of the heater assembly. This compression provides the necessary pressure for proper heat transfer between the heater assembly and the disposable set. Preferably, the covers are retained in the closed position by frictional engagement with the disposable set. Alternatively, any suitable latching or retaining mechanism may be provided.

Also, the covers 16 do not block the view of the bulk of the mid portion of the disposable set 18, allowing the operator to view the fluid passing through the disposable set. The disposable set is also keyed to the main body 14 in any suitable manner so that it fits within the compartment in the correct orientation. For example, one end 47 of the disposable set may be rounded to fit within an correspondingly rounded portion 49 of the compartment 38. The disposable set may include an arrow 50 thereon to provide an indication of the direction of flow, so that the disposable set is inserted in the housing in the correct orientation. The covers do not block this arrow. Also, the main body preferably includes indicator lights, such as LEDs, thereon. For example, one LED 52 may provide an indication of temperature at the output port, and another LED 54 may provide an indication that the heater is connected to the power source. The covers do not block these indicator lights either.

In one embodiment, the covers 16 can be maintained in two positions on the main body or can be removed fully from the main body. While on the main body, the covers can be in a fully closed position or an open position. The covers can include magnets or Hall Effect devices or other proximity sensors that interface with a corresponding component within the main body to determine the positions of the covers and cause operation of any appropriate switches. In a further embodiment, the covers can be maintained in a third or intermediate, half closed, position on the main body, described further below.

More particularly, in the fully closed position, (see FIG. 1), the covers 16 apply full pressure to the disposable set 18 to ensure good thermal contact with the heater assembly. In this position, the sliding covers can also be used to turn the power on to commence warming and/or to activate any audible or visible alarm(s). In the half closed position (see FIG. 2), the disposable set is still held in place by the covers, but warming is stopped, the audible alarm is silenced, and the visual indicators are turned off. The status LED could be flashed in battery operation to inform the user that the warmer is connected to the battery and draining. When the covers are in the open position (see FIG. 3), the disposable set 18 can be inserted and removed. No heating takes place, the audible alarm is silenced, and visual indicators are turned off. The status LED could be flashed in battery operation to inform the user that the heater is connected to the battery and draining.

Any suitable latching or retaining mechanism can be provided to retain the covers in the desired positions relative to the main body. For example, as shown in FIGS. 5 and 6, recessed surfaces 62 are provided on the main body 14 that latch with corresponding tabs 64 on the covers in the open position, preventing the covers from readily coming off the main body. Also, the tabs 64 abut surfaces 63 to hold the covers in the closed position. Finger grips 68 are provided to aid in grasping the covers to push or pull them to the desired position. The closed (and power on) position can be indicated by arrows 70 and an adjacent “ON” marking on the covers. Similarly, the open (and power off) position can be indicated by arrows 72 and an adjacent “OFF” marking on the covers. The covers can be fully removed from the main body in any suitable manner, for example, by the insertion of a suitable tool, such as a screw driver or dime, to lift the tab 64 over the surfaces 62. Alternatively, a latching or retaining mechanism can be configured to release simply by the use of sufficient force. Removal of the covers allows the device to be readily cleaned. Alternatively, passageways in the interior surfaces of the covers and a water tight main body housing allow cold sterilization by dipping in a sterilization fluid without complete removal of the covers.

Referring to FIG. 8, the sliding covers 14 may include opposed faces 74 that include gripping teeth thereon to form gripping faces. The gripping faces can be used to grip hospital clothing or bedding and hold the warmer in place to reduce stress on the IV line when the covers are fully closed.

In another aspect of the present invention, power to the heater can be increased or decreased to adjust the fluid temperature to ensure that the fluid is at an appropriate temperature when it reaches the patient. More particularly, some IV fluids that have been warmed are administered at very low flow rates. These fluids cool as they travel down the IV tubing to the patient. The greater the difference between ambient temperature and the fluid temperature, the greater the radiated heat losses from the IV tubing.

A suitable controller is provided to perform the calculations and communicate with the heater to make the desired adjustments. Heater power is determined by the difference between a target temperature (typically in the range of 39 to 41° C.), and the actual fluid temperature.

Referring to FIG. 9, the temperature drop across the heat exchanger is calculated (step 102). This temperature drop is equal to the heater power divided by the thermal resistance of the heater assembly. The thermal resistance can be readily determined by one of skill in the art from the thickness, thermal conductivity and area of the materials between the heater and the fluid and stored as a constant.

Then, the controller calculates the temperature loss of the IV tubing to the environment (step 104). First, the difference between the fluid target temperature and the ambient temperature is determined. The temperature loss is equal to this temperature difference multiplied by the radiation loss and divided by the heater power. The ambient temperature is measured by a suitable sensor located within the warming device in close contact with the housing, which is very close to ambient temperature. The radiation loss is a constant that is derived from experimentation with various lengths of the IV tubing and various flow rates. See FIG. 11.

Next, at step 106, the controller determines if the IV tubing loss is greater than 1° C. Also at step 106, the controller also determines if the total drop along the IV tubing and across the heat exchanger is greater than a drop limit. The drop limit is the maximum temperature that the fluid can be artificially raised so that the allowable surface temperature on the heat exchanger is not exceeded, for example, no greater than 3° C. from the desired target temperature. If the answer at step 106 is Yes, the actual fluid temperature is calculated at step 108 as the measured fluid output temperature minus the drop limit. If the answer at step 106 is No, the actual fluid temperature is calculated at step 110 as the fluid output temperature in the IV tubing drop minus the IV tubing drop (from step 102) minus the heat exchanger drop (from step 104). Using the calculated value of the actual temperature, heater power is adjusted appropriately.

In this manner, heat loss along the IV tubing can be more efficiently controlled The system allows the fluid warming device to be located a bit farther from the infusion site and still deliver normothermic fluid.

The invention is not to be limited by what has been particularly shown and described, except as indicated by the appended claims. 

1. A fluid warming device, comprising: a housing comprising a main body, a heat exchange body receiving compartment, and a cover movably coupled to the main body between an open position and a closed position; a heater assembly disposed within the main body and having a heat conducting surface disposed proximate the heat exchange body receiving compartment; and a heat exchange body removably disposable in the heat exchange body receiving compartment of the main body and having an input port and an output port to couple the heat exchange body to tubing to flow a fluid to be warmed through the heat exchange body.
 2. The fluid warming device of claim 1, wherein the cover presses the heat exchanger against the heater assembly when in the closed position.
 3. The fluid warming device of claim 1, wherein the heat exchange body is keyed to the main body so that it fits within the compartment in the correct orientation.
 4. The fluid warming device of claim 1, wherein the heat exchange body can be removed from or inserted into the compartment while attached to IV tubing at the input port and the output port.
 5. The fluid warming device of claim 1, further comprising: one or more thermally conductive layers interposed between the heat exchange body and the heater assembly.
 6. The fluid warming device of claim 1, wherein the heat exchange body includes visible indicators, and the cover does not block the visible indicators when in the closed position.
 7. The fluid warming device of claim 6, wherein the visible indicators comprise: one or more indicator lights to provide visual information to a user of the device.
 8. The fluid warming device of claim 7, wherein the one or more indicator lights comprise one or more LEDs.
 9. The fluid warming device of claim 7, wherein the one or more indicator lights provide an indication of one or more of a temperature at the output port, that the heater is connected to a power source, or that the heater is connected to and draining a battery.
 10. The fluid warming device of claim 1, further comprising: a switch to provide power to the heater assembly when the cover is in the closed position and to disconnect power from the heater assembly when the cover is in the open position.
 11. The fluid warming device of claim 1, wherein the cover retains the heat exchange body when in the closed position while leaving a mid portion of the heat exchange body visible.
 12. The fluid warming device of claim 1, wherein the cover is movable to a half closed position in which the cover still retains the heat exchange body within the compartment in the main body.
 13. The fluid warming device of claim 1, wherein fluid flowing through the heat exchange body is visible.
 14. The fluid warming device of claim 1, further comprising: temperature sensors to sense a temperature of the heat exchange body and a temperature of the heater.
 15. A method of minimizing heat loss through IV tubing to a patient, comprising: a) determining a temperature drop across a heat exchange body of an IV fluid warming device; b) determining a temperature drop of the IV tubing to the environment, the IV tubing extending from the IV fluid warming device to the patient; c) determining if the temperature drop along the IV tubing is greater than a determined temperature limit; d) determining if the total temperature drop along the IV tubing and across the heat exchange body is greater than a determined drop limit; e) if the determined values from c) or d) are greater than their respective limits, determining the actual fluid temperature as a fluid output temperature minus the drop limit; f) if either of the determined values from c) or d) are not greater than their respective limits, determining the actual fluid temperature as a fluid output temperature minus the heat exchanger temperature drop; and g) adjusting power to the heat exchanger to achieve a desired output temperature.
 16. The method of claim 15, wherein determining the temperature drop across the heat exchange body comprises: dividing heater power of a heater assembly that heats the heat exchange body by the thermal resistance of the heater assembly.
 17. The method of claim 15, wherein determining the temperature drop of the IV tubing to the environment comprises: determining the difference between a fluid target temperature and ambient temperature, multiplying this difference by a radiation loss constant to get a result, and dividing the result by heater power of a heater assembly that heats the heat exchange body.
 18. The method of claim 15, wherein the heat exchange body comprises an input port, an output port, and a fluid flow path from the input port to the output port, wherein the input port is connected to an IV fluid line to receive a fluid and the output port is connected to the IV tubing to deliver the fluid through the IV tubing to the patient.
 19. The method of claim 18, wherein the IV fluid warming device further comprises: a housing comprising a main body, a heat exchange body receiving compartment, and a cover movably coupled to the main body between an open position and a closed position, wherein the heat exchange body is disposed in the heat exchange body receiving compartment; and a heater assembly disposed within the main body and having a heat conducting surface disposed proximate the heat exchange body receiving compartment such that the heat exchange body is in heat exchange communication with the heater assembly.
 20. A method of minimizing heat loss through IV tubing to a patient, comprising: a) providing a heat exchange body, coupled between an IV fluid source and the patient via IV tubing, to a heat exchange body receiving compartment of an IV fluid warming device that comprises a housing including a main body, the heat exchange body receiving compartment, a cover movably coupled to the main body between an open position and a closed position, and a heater assembly disposed within the main body and having a heat conducting surface disposed proximate the heat exchange body receiving compartment such that the heat exchange body is in heat exchange communication with the heater assembly; b) determining a temperature drop across the heat exchange body by dividing heater power of the heater assembly by the thermal resistance of the heater assembly; c) determining a temperature drop of the IV tubing to the environment, the IV tubing extending from the IV fluid warming device to the patient, by determining the difference between a fluid target temperature and ambient temperature, multiplying this difference by a radiation loss constant to get a result, and dividing the result by heater power of the heater assembly; d) determining if the temperature drop along the IV tubing is greater than a determined temperature limit; e) determining if the total temperature drop along the IV tubing and across the heat exchange body is greater than a determined drop limit; f) if the determined values from d) or e) are greater than their respective limits, determining the actual fluid temperature as a fluid output temperature minus the drop limit; g) if either of the determined values from d) or e) are not greater than their respective limits, determining the actual fluid temperature as a fluid output temperature minus the heat exchanger temperature drop; and h) adjusting power to the heat exchanger to achieve a desired output temperature. 